Rapid method for direct extraction of DNA from soil and sediments.

A rapid method for the direct extraction of DNA from soil and sediments was developed. The indigenous microorganisms in the soil and sediments were lysed by using lysozyme and a freeze-thaw procedure. The lysate was extracted with sodium dodecyl sulfate and phenol-chloroform. In addition to a high recovery efficiency (greater than 90%), the yields of DNA were high (38 and 12 micrograms/g [wet weight] from sediments and soil, respectively). This method generated minimal shearing of the extracted DNA. The crude DNA could be further purified with an Elutip-d column if necessary. An additional advantage of this method is that only 1 g of sample is required, which allows for the analysis of small samples and the processing of many samples in a relatively short (7 h) period.     

Detection of low numbers of bacterial cells in soils and sediments by polymerase chain reaction.

Polymerase chain reaction was used to amplify the low copy number of two 16S ribosomal gene fragments from soil and sediment extracts. Total DNA for polymerase chain reaction was extracted from 1 g of seeded or unseeded samples by a rapid freeze-and-thaw method. Amplified DNA fragments can be detected in DNA fractions isolated from seeded soil containing less than 3 Escherichia coli cells and from seeded sediments containing less than 10 cells. This research demonstrated that coupling polymerase chain reaction to direct DNA extraction improves sensitivity by 1 and 2 orders of magnitude for sediments and soils, respectively. This technique could become a powerful tool for genetic ecology studies.     

Detection of low numbers of bacterial cells in soils and sediments by polymerase chain reaction.

Polymerase chain reaction was used to amplify the low copy number of two 16S ribosomal gene fragments from soil and sediment extracts. Total DNA for polymerase chain reaction was extracted from 1 g of seeded or unseeded samples by a rapid freeze-and-thaw method. Amplified DNA fragments can be detected in DNA fractions isolated from seeded soil containing less than 3 Escherichia coli cells and from seeded sediments containing less than 10 cells. This research demonstrated that coupling polymerase chain reaction to direct DNA extraction improves sensitivity by 1 and 2 orders of magnitude for sediments and soils, respectively. This technique could become a powerful tool for genetic ecology studies.     

Real-time quantitative PCR assay on bacterial DNA: In a model soil system and environmental samples

Real-time quantitative PCR (RTQ-PCR) was used to quantify the bacterial target DNA extracted by three commonly used DNA extraction protocols (bead mill homogenization, grinding in presence of liquid nitrogen and hot detergent SDS based enzymatic lysis). For the purpose of our study, pure culture of Bacillus cereus (model organism), sterilized soil seeded with a known amount of B. cereus (model soil system) and samples from woodland and grassland (environmental samples) were chosen to extract DNA by three different protocols. The extracted DNA was then quantified by RTQ-PCR using 16S rDNA specific universal bacterial primers. The standard curve used for the quantification by RTQ-PCR was linear and revealed a strong linear relationship (r(2)=0.9968) with a higher amplification efficiency, e5=1.02. High resolution gel electrophoresis was also carried out to observe the effect of these extraction methods on diversity analysis. For the model soil system, the liquid nitrogen method showed the highest target DNA copy number (1.3 x 10(9) copies/microl). However, for both the environmental samples, the bead beating method was found to be suitable on the basis of the high target DNA copy numbers (5.38 x 10(9) and 4.01 x 10(8) copies/ml for woodland and grassland respectively), high yield (6.4 microg/g and 1.76 microg/g of soil for woodland and grassland respectively) and different band patterns on high resolution gel electrophoresis suggesting an overall high extraction efficiency. This difference in the extraction efficiency between the model soil system and environmental samples may be attributed to different affinity of seeded and native DNA to soil particles.     

Rapid method for separation of bacterial DNA from humic substances in sediments for polymerase chain reaction.

The polymerase chain reaction (PCR) was used to amplify an Escherichia coli 16S ribosomal gene fragment from sediments with high contents of humic substances. Total DNA was extracted from 1 g of E. coli seeded or unseeded samples by a rapid freeze-and-thaw method. Several approaches (use of Bio-Gel P-6 and P-30 and Sephadex G-50 and G-200 columns, as well as use of the Stoffel fragment) were used to reduce interference with the PCR. The best results were obtained when crude DNA extracts containing humic substances were purified by using Sephadex G-200 spun columns saturated with Tris-EDTA buffer (pH 8.0). Eluted fractions were collected for PCR analyses. The amplified DNA fragment was obtained from seeded sediments containing fewer than 70 E. coli cells per g. Because only 1/100 of the eluted fractions containing DNA extracts from 70 cells per g was used for the PCR, the sensitivity of detection was determined to be less than 1 E. coli cell. Thus, DNA direct extraction coupled with this technique to remove interference by humic substances and followed by the PCR can be a powerful tool to detect low numbers of bacterial cells in environmental samples containing humic substances.     

Rapid method for separation of bacterial DNA from humic substances in sediments for polymerase chain reaction.

The polymerase chain reaction (PCR) was used to amplify an Escherichia coli 16S ribosomal gene fragment from sediments with high contents of humic substances. Total DNA was extracted from 1 g of E. coli seeded or unseeded samples by a rapid freeze-and-thaw method. Several approaches (use of Bio-Gel P-6 and P-30 and Sephadex G-50 and G-200 columns, as well as use of the Stoffel fragment) were used to reduce interference with the PCR. The best results were obtained when crude DNA extracts containing humic substances were purified by using Sephadex G-200 spun columns saturated with Tris-EDTA buffer (pH 8.0). Eluted fractions were collected for PCR analyses. The amplified DNA fragment was obtained from seeded sediments containing fewer than 70 E. coli cells per g. Because only 1/100 of the eluted fractions containing DNA extracts from 70 cells per g was used for the PCR, the sensitivity of detection was determined to be less than 1 E. coli cell. Thus, DNA direct extraction coupled with this technique to remove interference by humic substances and followed by the PCR can be a powerful tool to detect low numbers of bacterial cells in environmental samples containing humic substances.     

A Simple Silica-based Method for Metagenomic DNA Extraction from Soil and Sediments

A new method is described for extraction of metagenomic DNA from soil and sediments which is based on DNA adsorption to silica without the use of phenol, ethanol precipitation or a cesium chloride gradient. High-quality DNA was obtained, and PCR inhibition was overcome by adding bovine serum albumin and adjusting magnesium concentration. By using PCR-DGGE with Firmicutes and lactic acid bacteria-specific primers the extracted metagenomic DNA was shown to contain a mixture of bacterial genomes. This method can be used for screening bacterial diversity in soil and sediment samples.     

Land use intensity controls actinobacterial community structure

Actinobacteria are major producers of secondary metabolites; however, it is unclear how they are distributed in the environment. DNA was extracted from forest, pasture and cultivated soils, street sediments (dust and material in place), and sediments affected by animal activity (e.g. guano, vermicompost) and characterised with two actinobacterial and a bacterial-specific 16S rDNA primer set. Amplicons (140/156) generated with the two actinobacterial-specific and amplicons (471) generated with bacterial-specific primers were analysed. Amplicons from actinobacterial-specific primer were disproportionately actinomycetal from animal-affected (soil) samples and street sediments and either verrucomicrobial (i.e. non-actinobacterial) and from a novel non-actinomycetal actinobacterial group for soils. Actinobacterial amplified ribosomal DNA restriction analysis and terminal restriction fragment length polymorphism fingerprints clustered by land use, with cultivated soils clustering apart from uncultivated soils. Actinobacterial amplicons generated with eubacterial primers were overwhelmingly from (116/126) street sediments; acidobacterial amplicons from soils (74/75). In two street samples, >90% of clones were actinomycetal. Actinomycetes are selected in terrestrial soils and sediments by cultivation, urbanisation and animal activity.     

Development and Application of a New Method To Extract Bacterial DNA from Soil Based on Separation of Bacteria from Soil with Cation-Exchange Resin

A new method for the extraction of bacterial DNA from soil has been developed. Soil samples of 50 g were dispersed, and bacteria were released by use of a cation-exchange resin; subsequently, bacteria were separated from soil particles by low-speed centrifugation and lysed with lysozyme and ionic detergent, and the DNA was then purified by CsCl-ethidium bromide equilibrium density centrifugation. The extracted DNA was of high molecular weight and sufficiently pure for restriction enzyme digestion, DNA-DNA hybridization, and amplification by the polymerase chain reaction. The advantages of the new method are that the separation of bacteria from soil is considerably faster than by repeated blending, more samples can be handled, and furthermore no aerosols are formed during separation. Also, we investigated whether the CsCl-ethidium bromide equilibrium density centrifugation could be replaced by purification using Gene-Clean. However, this method produced DNAs which were insufficiently pure for several types of analysis. The new method was used to study survival of a 2,4-dichlorophenoxyacetic acid (2,4-D)-degrading Pseudomonas cepacia DBO1 (pRO101) in unamended soil and in soil amended with 2,4-D. We found that the degrading strain, irrespective of inoculation level, was able to grow to the same high numbers in soil amended with 2,4-D, while the strain in nonamended soil were maintained at the inoculation level. Detection based on DNA extraction and subsequent dot blot DNA-DNA hybridization was in accordance with detection by plating on selective medium.     

用于微生物多样性分析的棉田土壤总DNA的提取

目的：探讨适用于微生物多样性研究的棉田土壤微生物总DNA提取方法。方法：采用4种方法提取不同连作和轮作处理的棉田土壤微生物总DNA,比较其纯度、产率、片段大小,并应用ARDRA技术验证其质量。结果：其中3种方法均可获得23kb的DNA片段,但不同方法提取的DNA的产率和纯度上有明显差异。改良CTAB-SDS法提取的DNA完整性好,得率为24.20μg.g-1干土,纯化后A260/A280和A260/A230为分别为1.80和1.70,纯化回收率可达70.1%,完全适用于后续的PCR分析。结论：采用该法提取棉田土壤总DNA简便而高效。对该法提取获得的棉田土壤微生物总DNA进行ARDRA和DGGE分析,所得图谱能较全面地反映不同处理间微生物多样性及群落结构的差别,为不同栽培体系下棉田土壤微生物的分子生态学研究提供了基础。     

Quantification of the slug parasitic nematode Phasmarhabditis hermaphrodita from soil samples using real time qPCR

Phasmarhabditis hermaphrodita is a nematode parasite that infects and kills several species of slugs. The nematode is produced commercially as a biological control agent for slug pests of agriculture and horticulture. Given the difficulties of distinguishing this species from other nematode species in soil samples, very little is known about its natural ecology or its behaviour and persistence following application for biological control. Here we describe a method to quantify P. hermaphrodita in soil samples based on real time PCR. We designed primers and a dual labelled fluorescent probe that can be used to quantify numbers of P. hermaphrodita and which is capable of distinguishing this species from the morphologically identical Phasmarhabditis neopapillosa. We compared different methods whereby the entire nematode community is extracted prior to DNA extraction, and three methods to extract DNA directly from soil samples. Both nematode extraction and DNA extraction from large (10 g) samples of soil gave reliable estimates of nematode numbers, but methods which extracted DNA from small (1 g or less) soil samples substantially underestimated numbers. However, direct extraction of DNA from soils may overestimate numbers of live nematodes as DNA from dead nematodes was found to persist in soil for at least 6 days. The technique could be modified for detection and quantification of all soil borne parasitic nematodes.     

Microbial diversity in lake sediments detected by PCR-DGGE

In this study,PCR-denaturing gradient gel electrophoresis (DGGE) was applied to analyze the microbial communities in lake sediments from Lake Xuanwu,Lake Mochou in Nanjing and Lake Taihu in Wuxi.Sediment samples from seven locations in three lakes were collected and their genomic DNAs were extracted.The DNA yields of the sediments of Lake Xuanwu and Lake Mochou were high (10 μg/g),while that of sediments in Lake Taihu was relatively low.After DNA purification,the 16S rDNA genes (V3 to V5 region) were amplified and the amplified DNA fragments were separated by parallel DGGE.The DGGE profiles showed that there were five common bands in all the lake sediment samples indicating that there were similarities among the populations of microorganisms in all the lake sediments.The DGGE profiles of Lake Xuanwu and Lake Mochou were similar and about 20 types of micro-organisms were identified in the sediment samples of both lakes.These results suggest that the sediment samples of these two city lakes (Xuanwu,Mochou) have similar microbial communities.However,the DGGE profiles of sediment samples in Lake Taihu were significantly differ-ent from these two lakes.Furthermore,the DGGE pro-files of sediment samples in different locations in Lake Taihu were also different,suggesting that the microbial communities in Lake Taihu are more diversified than those in Lake Xuanwu and Lake Mochou.The differences in microbial diversity may be caused by the different environmental conditions,such as redox potential,pH,and the concentrations of organic matters.Seven major bands of 16S rDNA genes fragments from the DGGE profiles of sediment samples were further re-amplified and sequenced.The results of sequencing analysis indicate that five sequences shared 99%-100% homology with known sequences (Bacillus and Brevibacillus,uncultured bacteria),while the other two sequences shared 93%-96% homology with known sequences (Acinetobacter,and Bacillus).The study shows that the PCR-DGGE tech-nique combined with sequence analysis is a feasible and efficient method for the determination of microbial com-munities in sediment samples.     

Optimization of methods for detecting Mycobacterium avium subsp. paratuberculosis in environmental samples using quantitative, real-time PCR

Detection of Johne's disease, an enteric infection of cattle caused by Mycobacterium avium subsp. paratuberculosis (M. paratuberculosis), has been impeded by the lack of rapid, reliable detection methods. The goal of this study was to optimize methodologies for detecting M. paratuberculosis in manure from an infected dairy cow or in contaminated soil samples using a quantitative, real-time PCR (QRT-PCR) based analysis. Three different nucleic acid extraction techniques, the efficiency of direct versus indirect sample extraction, and sample pooling were assessed. The limit of detection was investigated by adding dilutions of M. paratuberculosis to soil. Results show that the highest yield (19.4+/-2.3 microg(-1) DNA extract) and the highest copy number of the targeted M. paratuberculosis IS900 sequence (1.3+/-0.2x10(8) copies g(-1) manure) were obtained with DNA extracted from manure using Qbiogene's Fast DNA Spin kit for soil. Pooling ten samples of M. paratuberculosis-contaminated soil improved the limit of detection ten fold (between 20 and 115 M. paratuberculosis cells g(-1) soil). Detection was between 65% and 95% higher when samples were extracted directly using bead-beating than when using pre-treatment with cell extraction buffers. The final soil-sampling and extraction regime was applied for detection of M. paratuberculosis in pasture soil after the removal of a M. paratuberculosis culture positive dairy cow. M. paratuberculosis remained in the pasture soil for more than 200 days. Results from these studies suggest that DNA extraction method, sampling protocol and PCR conditions each critically influence the outcome and validity of the QRT-PCR analysis of M. paratuberculosis concentrations in environmental samples.     

Rapid method for detecting Desulfitobacterium frappieri strain PCP-1 in soil by the polymerase chain reaction

A rapid method was developed for detecting in soil Desulfitobacterium frappieri strain PCP-1, an anaerobic gram-positive bacterium, isolated from a methanogenic consortium degrading pentachlorophenol. The method involved the establishment of a protocol for extracting total DNA from soil with the least contamination, and the use of the polymerase chain reaction (PCR) to detect strain PCP-1 with primers targeted with PCP-1 16S rRNA. To optimize the DNA extraction conditions, a glass mill homogenizer and a low-salt buffer containing polyvinylpolypyrrolidone were used on a black soil rich in organic matter. Recovered DNA was further purified with phenol/chloroform extractions, ammonium acetate precipitation and a G200 Sephadex gel-filtration column. DNA was extracted from soil supplemented with different concentrations of PCP-1 cells. Detection of PCP-1 was by PCR. The limit of detection was 800 added PCP-1 cells/g dry soil. This level of detection was achieved when the T4 gene-32 protein and 1 μg soil DNA were added to the PCR mixture followed by a nested PCR. This method is quick, sensitive, and can process several samples at the same time. Received: 22 October 1996 / Received revision: 24 January 1997 / Accepted: 10 February 1997     

Phylogenetic analysis of the bacterial communities in marine sediments.

For the phylogenetic analysis of microbial communities present in environmental samples microbial DNA can be extracted from the sample, 16S rDNA can be amplified with suitable primers and the PCR, and clonal libraries can be constructed. We report a protocol that can be used for efficient cell lysis and recovery of DNA from marine sediments. Key steps in this procedure include the use of a bead mill homogenizer for matrix disruption and uniform cell lysis and then purification of the released DNA by agarose gel electrophoresis. For sediments collected from two sites in Puget Sound, over 96% of the cells present were lysed. Our method yields high-molecular-weight DNA that is suitable for molecular studies, including amplification of 16S rRNA genes. The DNA yield was 47 micrograms per g (dry weight) for sediments collected from creosote-contaminated Eagle Harbor, Wash. Primers were selected for the PCR amplification of (eu)bacterial 16S rDNA that contained linkers with unique 8-base restriction sites for directional cloning. Examination of 22 16S rDNA clones showed that the surficial sediments in Eagle Harbor contained a phylogenetically diverse population of organisms from the Bacteria domain (G. J. Olsen, C. R. Woese, and R. Overbeek, J. Bacteriol. 176:1-6, 1994) with members of six major lineages represented: alpha, delta, and gamma Proteobacteria; the gram-positive high G+C content subdivision; clostridia and related organisms; and planctomyces and related organisms. None of the clones were identical to any representatives in the Ribosomal Database Project small subunit RNA database. The analysis of clonal representives in the first report using molecular techniques to determine the phylogenetic composition of the (eu)bacterial community present in coastal marine sediments.     

Extraction of DNA from soil using nanoparticles by magnetic bioseparation

Aims: To develop a simple, rapid and inexpensive soil DNA extraction protocol. Methods and Results: The protocol relies on the use of superparamagnetic silica‐magnetite nanoparticles for the isolation and purification of DNA from soil samples. DNA suitable for use in molecular biology applications was obtained from a number of soil samples. Conclusions: The DNA extracted using the tested method successfully permitted the PCR amplification of a fragment of the bacterial 16S rDNA gene. The extracted DNA could also be restriction endonuclease digested. Significance and Impact of the Study: The protocol reported here is simple and permits rapid isolation of PCR‐ready soil DNA. The method requires only small quantities of soil sample, is scalable and suitable for automation.     

Cryptococcus spp. DNA extraction from environmental samples

The genus Cryptococcus encompasses 38 species, but only 3 are associated with disease in humans and animals, Cryptococcus laurentii, Cryptococcus albidus and Cryptococcus neoformans. The last one is the most frequently reported. The disease is acquired by the inhalation of infectious propagules present in the environment. The habitat has been established using extraction techniques with buffer supplemented with antibiotics and plating in selective media. The aim of this work was to evaluate several DNA extraction techniques for Cryptocococus spp. from environmental samples. The control isolates were C. neoformans, C. albidus, C. laurentii and Paracoccidiodes brasiliensis. We also used vermiculita and soil samples contaminated with different yeast concentrations (10 to 10(6) cells/g) and samples naturally contaminated with C. neoformans. DNA was extracted with physical and chemical methods and with a commercial kit, and the DNA was purified with agarose blocks and silica columns. For the PCR amplification we used the CN4-CN5 primers, which are specific for C. neoformans. Only the commercial kit allowed DNA extraction and amplification from contaminated soil samples up to a concentration of 10 cells/g and from one sample naturally colonized. With this work we extracted and amplified DNA from Cryptococcus spp. from environmental samples with appropriate PCR specificity, it will be a tool to establish the ecological areas of C. neoformans in our country.     

Estimation of bacterial cell numbers in humic acid-rich salt marsh sediments with probes directed to 16S ribosomal DNA

The feasibility of using probes directed towards ribosomal DNAs (rDNAs) as a quantitative approach to estimating cell numbers was examined and applied to study the structure of a bacterial community in humic acid-rich salt marsh sediments. Hybridizations were performed with membrane-bound nucleic acids by using seven group-specific DNA oligonucleotide probes complementary to 16S rRNA coding regions. These included a general eubacterial probe and probes encompassing most members of the gram-negative, mesophilic sulfate-reducing bacteria (SRB). DNA was extracted from sediment samples, and contaminating materials were removed by a series of steps. Efficiency of DNA extraction was 48% based on the recovery of tritiated plasmid DNA added to samples prior to extraction. Reproducibility of the extraction procedure was demonstrated by hybridizations to replicate samples. Numbers of target cells in samples were estimated by comparing the amount of hybridization to extracted DNA obtained with each probe to that obtained with a standard curve of genomic DNA for reference strains included on the same membrane. In June, numbers of SRB detected with an SRB-specific probe ranged from 6.0 x 10(7) to 2.5 x 10(9) (average, 1.1 x 10(9) +/- 5.2 x 10(8)) cells g of sediment-1. In September, numbers of SRB detected ranged from 5.4 x 10(8) to 7.3 x 10(9) (average, 2.5 x 10(9) +/- 1.5 x 10(9)) cells g of sediment-1. The capability of using rDNA probes to estimate cell numbers by hybridization to DNA extracted from complex matrices permits initiation of detailed studies on community composition and changes in communities based on cell numbers in formerly intractable environments.     

Rapid method for the detection of genetically engineered microorganisms by polymerase chain reaction from soil and sediments

A rapid and sensitive method for the detection of genetically engineered microorganisms in soil and sediments has been devised by in vitro amplification of the target DNAs by a polymerase chain reaction. A cloned catechol 2,3-dioxygenase gene located on the recombinant plasmid pOH101 was transferred to Pseudomonas putida MMB2442 by triparental crossing and used as a target organism. For the polymerase chain reaction from soil and sediment samples, the template DNA was released from a 100-mg soil sample. Bacterial seeded soil samples were washed with Tris-EDTA buffer (pH 8.0) and treated with a detergent lysis solution at 100°C. After addition of 1% polyvinylpolypyrrolidine solution, the samples were boiled for 5 min. Supernatant containing nucleic acid was purified with a PCR purification kit. The purified DNA was subjected to polymerase chain reaction, using two specific primers designed for the amplification of catechol 2,3-dioxygenase gene sequences. The detection limit was 10² cells per gram of soil. This method is rapid and obviates the need for lengthy DNA purification from soil samples. Received 28 February 1997/ Accepted in revised form 23 November 1997     

Development of a molecular detection method for naphthalene degrading pseudomonads

Abstract: A combined polymerase chain reaction amplification and reverse dot blot assay was designed for the detection of bacterial genes from soil and sediments. Total nucleic acids were directly extracted from soil using a lysozyme/sodium dodecyl sulfate/freeze-thaw method followed by rapid purification through gel electrophoresis. DNA was amplified using a highly stringent polymerase chain reaction with primers directed against the nahR regulatory gene present in plasmid NAH7 of Pseudomonas putida G7. The resulting amplification product was detected colorimetrically by reverse dot blot with an improved sensitivity ten-fold greater than traditional ethidium bromide staining after gel electrophersis. A lower limit of 10³, P. putida G7 cfu (g soil)⁻¹ was detected. This method was successfully employed to detect indigenous naphthalene-degrading bacteria from subsurface sediment collected from different locations of a naphthalene-contaminated site. Similar approaches could be developed for other soil-borne genetic markers.